Insect collection device

ABSTRACT

An insect collection device ( 10 ) comprises an elongated housing ( 20 ) extending in a downstream direction between first ( 22 ) and second ( 24 ) ends about a housing interior. A partition ( 36 ) separates the interior ( 26 ) into an upstream region proximate the first end ( 22 ) and a downstream region proximate the second end ( 24 ). The partition ( 36 ) is constructed to permit airflow between these regions, while impeding passage of insects therebetween. A movable closure ( 50 ) is disposed on a first end portion ( 33 ) of the housing to move between a closed position and an open position to create an entryway into the upstream region. A compression chamber ( 70 ) is disposed on a second end portion of the housing ( 20 ) and moves between compressed and uncompressed positions to urge the closure into the second/open position such that insects in a vicinity of the first end ( 22 ) are drawn into the upstream region for collection. A methodology for capturing insects is also provided.

RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application Ser. No. 60/213,008 filed on Jun. 21, 2000.

FIELD OF THE INVENTION

The present invention generally relates to the field of insect collection and/or removal. More particularly, the present invention concerns an insect collection device which may be manually actuated to draw insects into an interior region for collection or extermination. The present invention also provides a method for capturing insects.

BACKGROUND OF THE INVENTION

Insects are among the most industrious animals on Earth, capable of living in almost any land habitat. Nearly one million species of insects are known to exist, many of which serve industrially beneficial uses in the ecosystem, while others are capable of destroying crops, trees, and houses and even carry harmful diseases such as malaria. Insects also provide a source of enjoyment or entertainment for some whose hobby is their collection, and others who keep insects as pets by maintaining ant farms, beehives and the like. Perhaps for most others, however, insects are considered pests that bite or sting and appear in unwanted places such as homes, offices, restaurants, and the like.

Many different types of pest control products are available to alleviate such nuisances. For example, topical skin creams and sprays help deter insects from stinging or biting. Similarly, insecticides are used by many in homes and other indoor areas to help prevent insects from entering. However, while these types of treatments may temporarily lessen the nuisance attributed to insects, they are generally ineffective at alleviating the problem in its entirety.

When insects enter indoor areas, many are likely to remove or exterminate them. Depending on the extent of the problem, it may be necessary to consult a certified exterminator to alleviate the problem. Perhaps the most common, and simplest way of killing and removing an insect, however, is through the use of a flyswatter or other crude concoction such as a rolled-up newspaper. Commercially available flyswatters are both practical and inexpensive and typically have a long handle for reaching insects that have alighted from high or hard to reach areas. Though simple and efficient, the drawback to these types of techniques is the unsightly remnants of the insects which are left behind on walls or windows, necessitating an additional clean-up step for the individual. Other known insect extermination techniques include flypaper and “bug lights” which serve to both attract and kill the flying insect. These types of devices, however, also have certain drawbacks that make their use indoors impractical because they are only efficient at killing insects in designated locations and also require subsequent removal of the exterminated pests.

Vacuum cleaners provide an attractive alternative to the aforementioned devices and have long been used to assist in the removal or extermination of insects. Vacuum cleaners typically do not present the individual with an additional clean-up step and provide a more sanitary and practical approach to removing insects from indoor areas. Vacuum cleaners are also more capable in removing insects due to the use of various attachments that extend the reach of the hose, narrow or widen the extent of the vacuum area, or provide special shapes that allow easy use for certain areas. Some attachments have been specifically designed to make the vacuum cleaner a more efficient tool for removing insects. For example, U.S. Pat. Nos. 4,279,095 to Aasen; 4,630,329 to Shores, and 4,488,331 to Ward each disclose attachments made for use with vacuum cleaners for the distinct purpose of capturing and removing insects.

While the collection of insects with a vacuum cleaner does not involve some of the uncleanly aspects of other conventional approaches, it too is not without certain disadvantages. For example, the length of an electrical cord or the length of the hose will limit the reach of many vacuum cleaners. Also, some vacuum cleaners can be cumbersome and awkward to maneuver, presenting a precarious situation for an operator requiring the use of a chair or a ladder to reach the insect. Finally, many vacuum cleaners have such a strong vacuum effect that the insect is killed once it is contained within the bag or other capturing device, such that these types of devices are not an attractive alternative for those individuals who want to capture insects for collection purposes.

There are several types of insect collection devices that have been designed to remedy some of these drawbacks. For example, U.S. Pat. No. 5,175,960 and related U.S. Pat. No. 5,402,598, both to Wade, disclose a collection device designed as a handheld battery operated vacuum. Although this device is not as cumbersome as some vacuum cleaners, or limited by the length of an electrical cord, its reliance on batteries to generate the necessary vacuum creates a different disadvantage. In addition to adding a separate expense, batteries have a limited useful life requiring that be replaced or recharged to properly operate the device. As the battery begins to expire, it becomes less capable of capturing the insects. Since the operator may not be aware of the battery's power, the device is less dependable, and capable of failure at an inopportune time. Another example is U.S. Pat. No. 4,733,495 to Winnicki that discloses a handheld device wherein the insect is drawn into the device by means of a vacuum. Although this device is not dependent upon a separate power source, the vacuum is generated by the movement of a tube from a retracted position to an extended position. This requires the operator to ascertain the appropriate distance from which to hold the device from the insect to be captured. As a result, if the device is used incorrectly, the forward thrusting of the tube can potentially cause damage to walls, glass, or other surfaces on which the insect is found.

Accordingly, there remains a need to provide a new design and construction for an insect removal device that is easy to hold, does not require the an external power source, and that effectively captures the insect such that it does not escape. There is a further need to provide a design and construction for an insect removal device that is portable, easy to use and easy to manufacture and maintain. The present invention is directed to meeting these needs.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a new and useful device for the collection and/or removal of insects

It is another object of the present invention to provide an insect collection device that uses a vacuum effect created by manual actuation to draw in and trap insects.

A further object of the present invention is to provide an insect collection device which is adaptable for use in hard to reach areas, such as crevices and other small enclosures, while alleviating the cleanup mess associated with known techniques.

It is yet another object of the present invention to provide an insect collection device that is lightweight, reusable, easy to use, and provides a sanitary way of collecting and removing insects for use in indoor areas.

A still further object of the present invention is to provide an insect collection device with a viewing area to give the operator the ability view the captured insects, and to determine when the device needs to be cleaned.

Yet another object of the present invention is to provide an insect collection device that is easy to clean because it can be disassembled.

It is another object of the present invention to provide an insect collection device having a mechanism capable of trapping the collected insect so as to prevent the insect from escaping the collection area.

Yet another object of the present invention is to provide an insect collection device that is relatively inexpensive and easy to manufacture and inexpensive to purchased.

In accordance with these objectives, an insect collection device comprises an elongated and preferably tubular housing having a first end and extending from the first end in a downstream direction to terminate at a second end to define a housing interior. A partition separates the housing interior into a first/upstream region proximate to the first end and a second/downstream region proximate to the second end. The partition is constructed to permit air to flow between the first and second regions while impeding the passage of insects therebetween. A movable closure is disposed on a first end portion of the housing and moves between a first (closed) position to hinder access to the upstream region from the first end and a second (open) position to create an entryway into the upstream region from the first end. A compression chamber is disposed on a second end portion of the housing and operates when moved from a compressed position to an uncompressed position to urge the closure into the open position such that insects in a vicinity of the first end are drawn into the upstream region for collection.

Preferably, the compression chamber is in fluid communication with the downstream region of the housing and is also operative when moved from the uncompressed position to the compressed position to eject air from the housing interior and to create a vacuum within the housing interior when allowed to move from the compressed position to the uncompressed position. The insect collection device of the present invention also preferably includes a triggering assembly that is operative when placed in an engaged state to retain the compression chamber in the compressed position, and when moved from the engaged state to a disengaged state, to allow the compression chamber to return to the uncompressed position. To this end, the triggering assembly may include a plunger shaft moveable with the compression chamber between a retracted position when the compression chamber is in the uncompressed position and an armed position when the compression chamber is in the compressed position. The triggering assembly further includes a trigger switch operative to engagedly retain the plunger shaft in the armed position, thereby to define the engaged state for the triggering assembly, and to release from the plunger shaft to allow the compression chamber to move from the compressed position to the uncompressed position, thereby to define the disengaged state for the triggering assembly. The plunger shaft preferably has its proximal end connected to a butt end of the compression chamber and extends from the proximal end into the housing interior to terminate at a distal end. The trigger switch is resiliently biased into engagement with a notch when the plunger shaft is in the armed position. This notch may be formed as a region of reduced thickness along a medial portion of the plunger shaft. Where a triggering assembly is provided, the housing is preferably formed to include a trigger guard which projects on opposite sides of a trigger button that is coupled to the trigger switch.

In another embodiment of the present invention, the insect collection device comprises a tubular housing and compression chamber as discussed above, as well as a collection member releaseably disposed on the housing's second end. The collection member may include a collection tube adapted to attach to the first end portion and having an outer surrounding sidewall which surrounds a collection region. A partition, as discussed above, is disposed within the collection tube to permit airflow between the collection region and the housing interior, while impeding the passage of insects therebetween. The moveable closure is disposed on an upstream end of the collection tube and moves between an open orientation whereby insects can be drawn into the collection region and a closed orientation to prohibit insects from entering into the collection region.

The moveable closure may be formed by a pair of trap doors. Alternatively, the moveable closure may include an annular ring which is sized and adapted to fit over the collection tube, and a plurality of closure flaps each having an attached portion secured to the webbing and a free portion to allow the closure flaps to swing about the attached portion as the compression chamber moves from the compressed position to the uncompressed position.

It is also preferred that the collection tube have a circumferential groove formed therein, with the partition formed as a screen mesh seated against this groove and tapered in the upstream direction toward the central longitudinally axis of the collection tube. With the exception of the primary housing section which supports the various components of the triggering assembly, etc., it is also preferred that the remaining upstream tubular sections of the insect collection device be transparent to allow for viewing of insects trapped therein.

In either of the above embodiments, it is preferred that the housing be selectively extensible to vary an effective length thereof. To this end, the housing extends along an central longitudinal axis and includes a plurality of tubular housing sections that are mateable with one another so that the effective length of the housing may be varied. Among these tubular housing sections is preferably a primary housing section that is releaseably attached to the compression chamber and formed by a pair of primary housing pieces that are mateable with one another. The compression chamber, which may be in the form of a flexible bellows, is attached to this primary housing section such as by a securement clamp. Where a plurality of tubular housing sections are provided, the moveable closure is disposed on a terminal, upstream one of these tubular housing sections.

It is preferred that the compression chamber be resiliently biased into the uncompressed position and that the moveable closure be biased into the closed position, yet urged into the open position as the compression chamber is returned to the uncompressed position from the compressed position. A purge valve may be associated with the housing and operates as the compression chamber moves from the uncompressed position to the compressed position to allow the air to escape from the housing interior.

The present invention also contemplates a method of capturing of insects. According to this methodology, an elongated retention tube is provided having a moveable closure at an upstream end portion that is biased into a closed position. Air is evacuated from the retention tube to establish a potential vacuum source therein. An upstream end portion of the retention tube is placed adjacent to a target insect, and air pressure is created within an interior upstream end portion of the retention tube that is less than ambient pressure at the upstream end whereby ambient air is drawn into the retention tube at a sufficient flow to cause the moveable closure to move into an open position and to draw the insect into the retention tube.

The method may also include a step of providing a compressible chamber at a downstream end portion of the retention tube, with the step of evacuating air from the retention tube being accomplished by compressing the chamber into a compressed position. Further, the step of creating air pressure within the upstream end portion of the retention tube that is less than ambient pressure may be accomplished by returning the compressible chamber to an uncompressed position. Finally, the step of evacuating air from the retention tube may be accomplished either before or after its upstream end portion is placed adjacent to the target insect.

These and other objects of the present invention will become more readily appreciated and understood from a consideration of the following detailed description of the exemplary embodiments of the present invention when taken together with the accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1(a) is a perspective view of the insect collection device according to a first exemplary embodiment of the present invention, and showing the device in the relaxed state;

FIG. 1(b) is a perspective view of the insect collection device of FIG. 1(a) and showing it in a ready state;

FIG. 2 is an exploded perspective view of the insect collection device of FIGS. 1(a) and 1(b) to show the various tubular housing sections thereof;

FIG. 3(a) is a partial right side view in elevation and in cross-section of the insect collection device when it is in the relaxed state;

FIG. 3(b) is a partial right side view in elevation and in cross-section view of the insect collection device when it is in the ready state;

FIG. 4 is an exploded perspective view of the insect collection device's primary housing section and its internal triggering assembly;

FIGS. 5(a) and 5(b) are each perspective views of the primary housing section's left housing piece;

FIGS. 6(a) and 6(b) are each perspective views of the primary housing section's right housing piece;

FIG. 7 is a side view in elevation and in cross-section of one of the housing's tubular sections;

FIG. 8 is a side view in elevation and in cross-section-of another of the housing's tubular sections;

FIG. 9 is a side view in elevation and in cross-section of the housing's collection tube section;

FIG. 10(a) is a side view in cross-section and in elevation of the housing's tubular sections in an assembled state;

FIG. 10(b) is a side view in cross-section and in elevation of two of the housing's tubular sections shown fully telescoped;

FIGS. 11(a) and 11(b) are cross-sectional views showing an upstream end portion of the insect collection device when the closure member is in the closed position and open position, respectively;

FIGS. 12(a) and 12(b) are perspective views showing the upstream end portion of the insect collection device when the closure member is in the closed position and open position, respectively;

FIGS. 13(a) and 13(b) are upstream end views of the closure member when it is in the closed position and open position, respectively;

FIG. 14 is a right side view in elevation and in cross-section of the insect collection device's compression chamber;

FIG. 15 is an end view in elevation of the insect collection device's securement clamp;

FIG. 16 is a left side view in elevation and in cross-section of the insect collection device's bellows pad;

FIG. 17 is a enlarged perspective view of the insect collection device's first plunger shaft bearing guide;

FIG. 18 is a enlarged perspective view of the insect collection device's second plunger shaft bearing guide;

FIG. 19 is a perspective view of the insect collection device's trigger switch;

FIG. 20 is a side view in elevation of the insect collection device's purge valve;

FIGS. 21(a) and 21(b) are each perspective views of the insect collection device's purge valve ring;

FIG. 22 is a right side view in elevation of an insect collection device according to the second exemplary embodiment of the present invention;

FIG. 23 is a right side view in elevation and in cross-section showing an upstream region for the insect collection device of FIG. 22;

FIG. 24 is a right side view in elevation and in cross-section of one of the housing's tubular sections;

FIG. 25 is a right side view in elevation of another of the housing's tubular sections;

FIG. 26 is a right side view in elevation and in cross-section of the tubular section of FIG. 25;

FIG. 27 is an exploded perspective view to illustrate the screen mount's attachment to the tubular section of FIG. 24;

FIG. 28 is a perspective view of the left piece which forms a component part for the primary housing section according to the second exemplary embodiment;

FIG. 29 is a perspective view of the right piece which forms a component part of the primary housing section for the second exemplary embodiment;

FIG. 30 is an exploded perspective view to illustrate the attachment of the collection nozzle to tubular section of FIGS. 25 and 26;

FIG. 31 is a somewhat enlarged perspective view of the collection nozzle's left piece;

FIG. 32 is a somewhat enlarged perspective view of the collection nozzle's right piece;

FIG. 33 is an exploded perspective view to illustrate the mounting of the closure member's trap doors to the collection nozzle;

FIG. 34 is a perspective view of a representative one the closure member's trap door;

FIG. 35 is a perspective view of a representative one of the spring clasps for use in attaching the trap door of FIG. 34 in the manner shown in FIG. 33;

FIG. 36 is a view in elevation and in cross-section of the screen mount;

FIG. 37 is a right side view in elevation of an insect collection device according to a third exemplary embodiment of the present invention and showing portions thereof in phantom; and

FIG. 38 is a right side view in elevation and in partial cross-section showing an insect collection device according to a fourth exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

The present invention, as shown and described with reference to the exemplary embodiments herein, eliminates the known drawbacks found in the prior art by providing an insect collection device that is easy to operate, requires no external power sources, and provides for easy manufacture and maintenance. The invention also provides an improved solution for the collection of live insects, as well as a means for exterminating captured insects. Referring more particularly to the drawings, a first exemplary embodiment of the insect collection device 10 of the present invention is introduced in FIGS. 1(a) and 1(b). Insect collection device 10 is in the form of a hand operated mechanism which can be placed in close proximity to a target insect and manually actuated to draw the target insect into a collection region through a suctioning effect. As shown in these figures, insect collection device 10 comprises an elongated and generally tubular housing 20, a moveable closure 50 and a compression chamber 70. Housing 20 extends about a housing interior along a central longitudinal axis “L” from a first upstream end 22 to terminate in a second downstream end 24. Moveable closure 50 is disposed on an upstream end portion of housing 20, while compression chamber 70 is disposed on a downstream end portion of housing 20. As will be discussed in greater detail below, moveable closure 50 is operative to move between a first (closed) position wherein insects in a vicinity of the upstream end 22 are prevented from entering into the housing's interior, to a second (open) position which creates an entryway into the upstream interior region of housing 20. As compression chamber 70 is selectively moved between an uncompressed position (FIG. 1(a)) and a compressed position (FIG. 1(b)), this controls the orientation of moveable closure 50.

In order to allow collection of insects in hard to reach areas, housing 20 is preferably an extensible member so that an effective length thereof may be selectively varied. To this end, housing 20 may include a plurality of plastic tubular sections 30-33 that are matable with one another so that the effective length of housing 20 may be varied. More particularly, housing 20 in this first exemplary embodiment includes a primary housing section 30, first and second extension tube sections 31 and 32 and a collection tube 33. Tubes 31-33 are shown in FIGS. 7-9, respectively.

With reference to FIG. 2, first extension tube section 31 has a circular cross section and is telescopically received over an upstream end portion of primary housing section 30 and retained there by frictional engagement. An upstream end of first extension tube 31 is provided with an inner circumferential ridge 34 so that when it is telescopically received over a downstream end portion of second extension tube 32, as shown in FIG. 10(a), and the effective length of tube sections 31 and 32 is increased, as shown in FIG. 10(b), ridge 34 is captured in an outer circumferential groove 35 formed in second extension tube 32 to prevent inadvertent separation during use. Also provided on second extension tube 32 is a circumferential O-ring seat 28 which receives an O-ring 29 to provide for a sealed engagement between tube sections 31 and 32. An upstream end portion of second extension tube 32 may then be telescopically received within collection tube 33 to form the extensible set of extension sections.

The construction of collection tube 33 may be appreciated with reference to FIGS. 2 and 9. Collection tube 33 may also be a tubular plastic piece having a circular cross-section that is formed to include inner and outer circumferential ridges 44 and 45, respectively. Disposed within collection tube 33 is a partition, preferably in the form of a mesh screen 36 which tapers in the upstream direction. Mesh screen 36 is constructed of an appropriate material, such as an integrally molded plastic piece or stamped aluminum, and preferably includes an annular ring 37 which is sandwiched between inner circumferential groove 44 and the upstream end of extension tube 32 when the device is assembled. Attached to annular ring 37 is a meshing 39 which is impervious to insects. Mesh screen 36 is sized and adapted to be press fit into collection tube 36 so that it does not dislodge once insects are collected and the collection tube is removed.

Moveable closure 50 in the first exemplary embodiment of the insect collection device 10 of the present invention is formed as an end cap that is disposed over an upstream end portion of collection tube 33. Moveable closure 50 is maintained on collection tube 33 by a snap-fit engagement. To this end, as shown in FIGS. 11(a) and 11(b), moveable closure 50 includes an annular ring section 49 provided with a lip 54 that is sized and adapted to engage an annular recess 47 formed in collection tube 33 adjacent to outer circumferential ridge 45. As such, moveable closure 50 fits snuggly over the upstream end portion of collection tube 33 to prevent dislodgment during use. Once the insect collection device 10 is in the assembled state, as shown in various ones of the figures, mesh screen 36 forms a partition which separates the housing interior 26 into an upstream insect collection region 25, generally defined within collection tube 33 between mesh screen 36 and moveable closure 50, and a downstream region 27 that is to the left of mesh screen 36 in the figures.

The remainder of the moveable closure's construction, and its ability to assume open and closed orientations can now be better appreciated with reference to FIGS. 12(a), 12(b), 13(a) and 13(b). Secured to the annular ring 49 of closure member 50 are a plurality of equiangularly spaced-apart closure flaps 51. Each of closure flaps 51 is a generally triangular and wedge-shaped member having two vertices 52 and 53 secured to an inner surface of annular ring 49 and a free vertex 54. Preferably, movable closure 50 is a one-piece molded plastic construction which has been die cut to form the closure flaps 51. When the closure flaps 51 are in the closed position (FIGS. 12(a) and 13(a)), they resemble a hub and spoke arrangement so that they essentially close off access to the collection region 25 from its upstream end. When in the closed orientation, and as perhaps best shown in FIG. 11(a), bent portions 55 of vertices 54 come together. However, when the vacuum effect is created by insect collection device 10, such that the pressure within the collection region 25 and the housing interior 26 is less than ambient pressure, closure flaps 51 are caused to fan out from one another as shown in FIGS. 11(b), 12(b) and 13(b) into the open position thereby providing an entryway into the collection region 25 as target insect(s) are drawn in. After this happens, and the pressure begins equalize, closure flaps 51 return to the closed position.

As shown in various one of the figures, compression chamber 70 is preferably in the form of a flexible bellows having a plurality of hinged ribs 72 joined together in an accordion-like manner so that compression chamber 70 can be moved between the uncompressed position and the compressed position. Because a vacuum effect is created in order to effectively capture insects in a vicinity of the housing's upstream end 22, it is preferred to securely attach compression chamber 70 to the downstream end portion 24 of housing 20. To this end, and as shown in FIG. 14, the compression chambers bellows structure is provided with an upstream neck 73 which is sized and adapted to be placed over the second end portion of housing 20. A securement clamp 74 (FIG. 15) is formed as a metallic ring that is sized to be placed over the compression chamber's neck 73 once the neck is received over the housing's first end portion. Securement clamp 74 is provided at one end thereof with a screw 75 which is adapted to threadedly engage a cooperative socket 76 formed on an opposing circumferential end of the securement clamp 74, as known in the art. In this manner, the tendency for the compression chamber 70 to become detached from the housing 20 upon use of insect collection device 10 is reduced. However, the ordinarily skilled artisan should readily appreciate that compression chamber 70 could be attached to housing 20 in a variety of different manners other than that described herein. In any event, though, it is preferred that compression chamber 70 be capable of securely, yet releaseably, attaching to the housing 20 so that the insect collection device 10 may be easily cleaned and reassembled as desired.

FIGS. 3(a) and 3(b) respectively show insect collection device 10 in a relaxed configuration wherein compression chamber 70 is in the uncompressed position, and a ready configuration wherein compression chamber 70 is in the compressed position. As may also be seen in these figures, insect collection device 10 includes a triggering assembly 80 which is mechanically coupled to compression chamber 70 and is operative when placed in an engaged state (FIG. 3(b)) to retain compression chamber 70 in the compressed position. Triggering assembly 80 is also operative upon activation by a user to move from the engaged state to a disengaged state (FIG. 3(a)) and thereby allow compression chamber 70 to return to the uncompressed position. Triggering assembly 80 broadly includes a metallic plunger shaft 84 that is moveable with compression chamber 70 between a retracted position when compression chamber 70 in the uncompressed position, and an armed position when compression chamber 70 is in the compressed position.

Triggering assembly 80 also includes a trigger button 86 and its associated trigger switch 82 which operates to engagedly retain plunger shaft 84 in the armed position. Plunger shaft 84 is disposed entirely within insect collection device 10 and travels longitudinally along its central longitudinal axis “L”. A proximal end 83 of plunger shaft 84 is secured to the butt end 77 of compression chamber 70 via a fastening screw 42 which extends through a pair of spaced-apart metallic washers 41 and 43 as well as a central bore 85 (FIG. 14) formed in the downstream end of bellows 70, such that a portion of the bellows is sandwiched therebetween. A corresponding bore (not shown) is also formed in the proximal end portion of plunger shaft 84 so that fastening screw 42 may be threadedly received therein. A resilient bellows pad 66 is then attached, such as via an acrylic adhesive, to the recess formed in the downstream end of compression chamber 70. As shown in FIG. 16, bellows pad 66 is provided with concentric cylindrical cut outs 65 and 67 which are, respectively, sized and adapted to accommodate the head of fastening screw 42 and washer 41. As such, bellows pad 66 provides a cushioned contact surface for a user's palm as he/she manually urges compression chamber 70 in the direction of the enlarged arrow in FIG. 3(b) so that it moves into the compressed position.

Plunger shaft 84 extends from its proximal end within the housing interior 26 along central longitudinal axis “L” to terminate at a plunger shaft distal end. A pair of longitudinally spaced apart plunger shaft bearing guides 60 and 62 are fixedly disposed relative to primary housing section 30 and serve to both rigidify the internal assemblage and provide guide ways for plunger shaft 84 as it travels in the longitudinal direction. First plunger shaft bearing 60 is shown in FIG. 17 as an integral plastic construction which includes a collar 54 which is concentric with a tubular section 56 and attached thereto by a plurality of equiangularly spaced apart fins 58. When in the assembled state, fins 58 are orientated so that they converge toward longitudinal axis “L” in the downstream direction. Tubular section 56 provides a first passageway through which plunger shaft 84 is received. When assembled, a first coiled compression spring 6 is seated between washer 43 and a downstream facing surface 57 of first plunger shaft bearing guide 60 in order to bias compression chamber 70 into the uncompressed state.

Second plunger shaft guide bearing 62 is also fixedly disposed within primary housing section 30 upstream of trigger switch 82 and, as shown in FIG. 18, also includes an associated collar 61, tubular section 63 and fins 64, such that associated tubular section 63 provides a second passageway for a corresponding portion of plunger shaft 84. A second compression spring 8 is disposed for compression between an upstream end 69 of second plunger shaft bearing guide 62 and a metallic washer 81 that is attached to the upstream end of plunger shaft 84 via an appropriate fastening screw 67. Second compression spring 8 serves the purpose of preventing the upstream end of plunger shaft 84 from traveling in the downstream direction beyond second plunger shaft bearing guide 62 as the plunger shaft moves from the armed position to the retracted position.

Trigger switch 82 is also disposed within housing interior 26 and extends transversely to longitudinal axis “L”. The construction of trigger switch 82 is shown in FIG. 19 and an integral plastic piece having a central annular portion 87 provided with a lobe-shaped opening 88 and a pair of oppositely projecting legs 89 and 90. Lobe-shaped opening 88 has an enlarged region 88′ which is sized and adapted to accommodate the larger cross-section region of plunger shaft 84, and a reduced region 88″ which is sized and adapted to accommodate a medial portion 85 of plunger shaft 84 that is of reduced thickness. As also shown in FIG. 19, lower leg 90 of trigger switch 86 has a tapered end 91 to facilitate movement of the trigger switch 86 during use.

Having discussed various aspects of the general construction for insect collection device 10, the assemblage thereof can now be better appreciated. Conveniently, primary housing section 30 is formed, as shown in FIGS. 5(a)-6(b), by matable pairs of primary housing pieces 28 and 29 to facilitate the assembly process. Each of these pieces 28 and 29 has an outwardly flared downstream portion 31 and 31′, respectively, so that when they are assembled housing section 30 has a generally conical portion sized and adapted to accommodate the neck 72 of compression chamber 70 and first bearing guide 60. Once the plunger shaft's proximal end has been fastened to the butt end of the compression chamber, and the bellows pad adhered to the compression chamber 70, the remainder of the assemblage can proceed as follows. Plunger shaft 84 can then be passed through first compression spring 6 and first plunger shaft bearing guide 60 so that first compression spring 6 is seated between washer 43 and seat 57. Then, the plunger shaft 84 is passed through the lobe-like opening 88 of trigger switch 82 as well as second plunger shaft guide bearing 62 and second compression spring 8. As appreciated with references to FIGS. 4 through 6(b), primary housing section pieces 28 and 29 are then appropriately positioned about this internal assemblage so that the collar 54 of first plunger shaft bearing guide 60 is aligned with opposed arcuate grooves 44 and 44′ formed in housing pieces 28 and 29, respectively. Similarly, second plunger shaft bearing guide 62 is appropriately positioned so that its collar 61 is aligned with opposed arcuate grooves 45 and 45′. A triggering spring 87 is then placed over lower trigger arm 90 and trigger button 86 is placed over upper arm 89. This sub-assemblage is then positioned so that lower arm 90 is seated within corresponding cut out sections 46 and 46′ formed in housing piece sections 28 and 29, respectively, while the cap of trigger button 86 is passed through opposed arcuate cut outs 47 and 47′ until the brim of trigger button 86 is resiliently urged into contact with the inner surfaces of pieces 28 and 29 by virtue of the restorative force of triggering spring 87. A purge valve 78 (FIG. 20) is then passed through its associated purge valve ring 79 (FIGS. 21(a) and 21(b) that has a hub and spoke-like construction. The purge valve ring 79 is then positioned within purge valve seat portions 48 and 48′ formed in pieces 28 and 29, respectively.

Once the internal triggering assembly 80 is assembled and positioned, such as in the manner discussed above, opposed primary housing section pieces 28 and 29 can then be mated with one another by press fitting them together such that the various alignment holes 12 associated with left housing piece 28 register with correspondingly positioned nubs 14 formed in second piece 29. Pieces 28 and 29 may then be securely fastened together with securement screws 16 which threadedly engage aligned openings 18 and 18′ formed in pieces 28 and 29, respectively. The neck 73 of bellows 70 can then be placed over collar sections 48 and 48′ associated with first and second pieces 28 and 29, respectively, and thereafter secured through the use of the securement clamp 74 as discussed above. As desired, one or more tubular extensions can then be selectively attached to primary housing section 30, as well as the assembled collection member 50 as also discussed hereinabove.

Once assembled, insect collection device 10 is ready for use. In operation, an individual prepares insect collection device 10 for use by grasping primary housing section 30 with one of his/her hands. Knurling and finger recess are provided for added comfort. Using the palm of his/her other hand, the user then compress bellows 70 against the restorative force of spring 6 into the compressed position of FIG. 1(b). This causes a corresponding movement of plunger shaft 84 in the upstream direction until the notched medial portion 85 of plunger shaft 84 which has a reduced thickness begins to pass through lobe-like opening 88 of trigger switch 82. The upward bias on trigger spring 87 then urges lobe-like opening 88 into contact with medial portion 85 so that medial portion 85 is seated within lower lobe portion 88″ of trigger 82. During this compression, air escapes through the purge valve 78 In the direction of arrows “A” in FIG. 3(b). This allows the insect collection device 10 to be placed in the armed state without pressurizing the interior and without causing moveable closure 50 to be inadvertently placed in the open position. The user can then relieve pressure on bellows 70 and the restorative force of spring 6 urges the shoulder of plunger shaft 84 into engagement with arm 90. At this point, insect collection device 10 is in a ready state with triggering assembly 80 correspondingly in an engaged position.

Once the user approaches a target insect whereby the upstream end 22 of housing 20 is positioned in close proximity to the target insect, the user depresses trigger button 86, thereby dislodging trigger 82 from medial portion 85. Trigger guards 19 and 19′ are provided on housing pieces 28 and 29 to help prevent inadvertent activation of the device prior to use. The restorative force of spring 6 then causes a vacuum effect within the housing interior as compression chamber 70 returns to the uncompressed state along with the corresponding movement of plunger shaft 84 to the retracted position. This vacuum effect urges closure 50 into the open position and, at the same time, draws the target insect into collection tube 33. As the suctioning effect reduces and the pressure within housing interior 26 begins to equalize with the ambient pressure, closure 50 is restored to its closed position, thereby confining the captured insect within collection tube 33 between screen 36 and closure 50. At this point, if desired, the process can be repeated to capture additional insects which can be viewed through collection tube 33 by virtue of its transparency.

A second exemplary embodiment of the insect collection device of the present invention will now be described with reference to FIGS. 22-36. Insect collection device 110 is generally introduced in FIG. 22 and, as with insect collection device 10 discussed above, comprises a housing 120, a moveable closure 150, a compression chamber 170 and a triggering assembly 180. Insect collection device 110 is constructed similarly to insect collection device 10 discussed above, with the exception that its upstream portion is somewhat different. Accordingly, only those portions of insect collection device 110 which differ from that discussed above with reference to the first exemplary embodiment will be described.

The upstream portion of insect collection device 110, when in the fully assembled state, is shown in FIG. 23. Housing 120 includes a pair of tubular and telescopically received housing section 130 and 140. As shown in FIG. 24, first tubular housing section 130 is provided with an inner circumferential ridge 138 at its upstream end. As shown in FIG. 25, second tubular housing section 140 is provided with an outer circumferential groove 142 and an outer circumferential ridge 144 along its downstream end portion so that when first tubular section 130 is telescopically received over second tubular section 140 as shown in FIG. 23, ridge 144 provides a limit stop for the extensible set as they are telescopically extended to their full length wherein it comes into contact with inner circumferential ridge 138. Also as before, an O-ring 143 is seated within outer circumferential groove 142 to provide a sealed engagement between the two housing sections. In this regard, the construction of the upstream portion of insect collection device 110 is similar to that discussed above with reference to the first embodiment.

As shown in FIGS. 28 and 29, however, the two pieces 121 and 122 of primary housing section 120 have their upstream ends constructed somewhat differently. Namely, these upstream ends 123 and 124 are enlarged and, respectively, provided with grooved portions 125 and 126 so that, a screen mount 160 can be seated therein when insect collection device 110 is in the assembled state. With reference again to FIG. 23, screen mount 160 is formed to include a screen profile which supports a tapered mesh screen 138 that is impervious to insects as there are drawn into collection region 125. The construction of the various pieces for the screen mounting sub-assembly may be best appreciated with reference to FIGS. 27 and 36. Screen mount 160 has a generally cylindrical main body provided with a generally circuitous brim 162 which is sized and adapted to engage grooved portions 125 and 126, respectively, of housing pieces 121 and 122 when in a mounted state so that screen mount 160 is fixedly positioned within an interior of insect collection device 110. A plurality of converging support posts 164 project from an opposing end of the main body of screen mount 160 to form the screen mount. Posts 164 supportably position a prong element 166. It should be noted that screen mount 160 is preferably constructed as a unitary piece of plastic material. A pre-formed, tapered mesh screen 138 having an aperture (not shown) is then sized and adapted to be placed over prong element 166 so that it drapes over these support posts 164. Screen 138 is held in this position by a notched clip mount 141.

A downstream end portion of tubular section 130 is attached to screen mount 160 via snap fit engagement prior to being clamped between primary housing pieces 121 and 122. More particularly, tubular section 130 is formed to include a pair of opposed arcuate cut outs 136 so that when a user grasps screen mount 160, finger tabs 161 thereof may be aligned with cut outs 136 to allow screen mount 160 to be inserted into tubular section 130. Thereafter, the user can then grasp cross piece 163 and press fit screen mount 160 into engagement with tubular section 130 whereby protrusions 165 snap into engagement with corresponding notches 134 formed on an inner surface of tubular section 130. With reference again to FIG. 23, screen mount 160 can be easily ejected from tubular section 130 by driving inner telescoping tubular section 140 in the downstream direction to separate the engagement of protrusions 165 from notches 134.

A bayonet connection is employed to fixedly mount moveable closure 150 to nozzle section 180. As shown in FIG. 30, second tubular section 140 is also provided with a pair of opposed protrusions 146 which are alignable with channels 182 associated with nozzle 180, whereby the tubular portion of nozzle 180 can be inserted within second tubular section 140 and rotated so that protrusions 146 become locked into notches 184 associated with nozzle 180. A compressible ring 170 may also be placed over nozzle 180 so that it is seated within collar 186 to provide a sealed engagement between nozzle 180 and an inner sidewall surface 145 of second tubular section 140 when they are mated.

Nozzle 180 is formed by a pair of matable pieces 181 (FIG. 31) and 191 (FIG. 32) which mount moveable closure 150. Reference will now be made to FIGS. 31-35 to describe the mounting assembly for moveable closure 150. Moveable closure 150 includes a pair of trap doors 152 and 154 which are mounted between nozzle pieces 181 and 191. A representative one of these doors 152 is shown in FIG. 34 to include an arcuate door panel 153 and a door hinge 155 having protruding ends. It should be appreciated, of course, that second door 191 has an identical construction. Each of doors 152 and 154, when in the mounted state, are resiliently biased into a closed position through the provision of an associated clip spring, such as clip spring 172 shown in FIG. 35. More particularly, and with reference to door 152, its associated spring 172 is placed such that its looped portion 173 is disposed about one leg of hinge 155. These are then aligned with a shaft hole 183 formed in first nozzle piece 181 so that when door 152 is mounted as shown in FIG. 33, an upper leg 174 of spring clip 172 rests against face panel 153, while a lower leg 176 of spring clip 172 rests against an inner surface of nozzle piece 181. Wall sections 185 and 195 are formed as part of nozzle pieces 181 and 191 to prevent first door 152 from swinging open outwardly beyond the opened position. Second door 154 is mounted between nozzle pieces 181 and 191 in a like manner. As such, it can be appreciated that doors 152 and 154 are resiliently biased into their closed position, yet permitted to swing into an open position upon creation of the vacuum effect discussed above with reference to the first exemplary embodiment for the insect collection device 10 of the present invention. Target insects are then drawn into collection region 125 where they are maintained between partition screen 138 and the trap doors. As may also be seen in various ones of the figures for this second exemplary embodiment for the insect collection device 110, nozzle 180 has internal threads 186 and 196 formed on its nozzle pieces 181 and 191. This allows a user, if desired, to threadedly attach a correspondingly threaded vessel within which the captured insect(s) are drawn and then trapped by replacing nozzle 180 with an appropriate closure cap.

A third exemplary embodiment of an insect collection device according to the present invention is shown in FIG. 37. As before, the discussion of insect collection device 210 will be confined to those portions which differ from embodiments discussed hereinabove. In insect collection device 210, that portion of primary housing section 220 which is upstream of trigger guard 219 has simply a tubular construction 222 which is telescopically received within first tubular section 230. FIG. 37 also shows second tubular section 240 telescopically received within first tubular section 230, as discussed above. Here, however, a collection vessel 270 has its neck 272 threadedly attached to the tubular portion 286 of nozzle 280. Vessel 270 has an open bottom and an inserted mesh screen 238 as described with reference to the first embodiment. The interior of vessel 270, thus, provides the confined collection region for the insects, thereby eliminating the need for the screen mount assembly discussed above with reference to the second exemplary embodiment.

In FIG. 38, a fourth exemplary embodiment of the insect collection device of the present invention is shown. Here, insect collection device 310 has its primary housing section 320 joined to tubular section 330 by a coupler 324 which surrounds an upstream end portion of primary housing section 320 and a downstream end portion of tubular section 330. Necessarily, then, coupler 324 has opposed openings within which primary housing section 320 and tubular section 330 may be inserted in a close-fitting, mated engagement. In a similar manner, an upstream end collar 380 telescopically receives an upstream end portion of 330 and mounts the trap doors of moveable closure 350 in a manner such as that discussed above with reference to the second exemplary embodiment. Also shown in this fourth exemplary embodiment is a mesh screen 338 which is formed by integrally molding tubular section 330 so that it is provided with a tapering basket weave section from which extends a prong 340 which supports a wick 370 that can be coated in any appropriate manner with insecticide to exterminate captured insects.

Having discussed the various exemplary embodiments for the construction of the insect collection device of the present invention, it should be readily appreciated that the present invention also contemplates a method of capturing insects. According to this method, an elongated retention tube is provided having a moveable closure at an upstream end portion that is biased into a closed position. Air is then evacuated from the retention tube to establish a potential vacuum source therein. An upstream end portion of the retention tube is then placed adjacent to a target insect, and air is created within an interior upstream end portion of the tube that is less than ambient pressure at the upstream end, whereby ambient air is drawn into the retention tube at a sufficient flow to cause the moveable closure to move into an open position and to draw the insect into the retention tube.

The methodology may also incorporate the step of providing a compressible chamber at a downstream end portion of the retention tube, with the compression chamber being biased into an uncompressed position. The step of evacuating air from the retention tube is accomplished by compressing the chamber into a compressed position, where it may be mechanically maintained. Further, the step of creating air pressure within the upstream end portion of the retention tube that is less than ambient pressure is accomplished by returning the compressible chamber to the uncompressed position.

Accordingly, the present invention has been described with some degree of particularity directed to the exemplary embodiments of the present invention. It should be appreciated, though, that the present invention is defined by the following claims construed in light of the prior art so that modifications or changes may be made to the exemplary embodiment of the present invention without departing from the inventive concepts contained herein. 

I claim:
 1. A manually actuated insect collection device, comprising: (a) a compression chamber; (b) an elongated housing having a housing proximal end joined to said compression chamber and extending from said housing proximal end a selected distance to terminate in a housing distal end thereby to define a housing interior; (c) a partition disposed within said housing between said housing proximal and distal ends to separate said housing interior into an upstream region adjacent to said housing distal end and downstream region adjacent to said housing proximal end, said partition constructed to permit airflow between said upstream and downstream regions while impeding passage of insects therebetween; (d) a movable closure disposed on a distal end portion of said housing and operative to move between an open orientation to create an entryway into said upstream region from said housing distal end and a closed orientation to hinder access to said upstream region front said housing distal end, wherein said compression chamber is operative upon actuation to move from an uncompressed position to a compressed position to eject air from said collection device and operative when allowed to return to the uncompressed position from the compressed position to create a vacuum within said housing interior and urge said closure to move into the open orientation so that insects in a vicinity of said housing distal end are drawn into said upstream region for collection, with said housing being immovable during actuation of said compression chamber from the uncompressed position to the compressed position; and (e) a triggering assembly coupled to said compression chamber and operative when placed in an engaged state to retain said compression chamber in the compressed position, said triggering assembly further operative when moved from the engaged state to a disengaged state to allow said compression chamber to return to the uncompressed position, said trigger assembly including a plunger shaft which extends from a plunger shaft proximal end into the housing interior to terminate at a plunger shaft distal end, there being a notch formed in said plunger shaft between said plunger shaft proximal and distal ends, said plunger shaft movable with said compression chamber between a retracted position when said compression chamber is in the uncompressed position and an armed position when said compression chamber is in the compressed position, and wherein said triggering assembly further includes a trigger switch that is resiliently biased into engagement with said notch to retain the plunger shaft in the armed position thereby to define the engaged state for said triggering assembly, said trigger switch operative upon release from said plunger shaft to allow said plunger shaft to move from the armed position to the retracted position, thereby to define the disengaged state for said triggering assembly.
 2. An insect collection device according to claim 1 including a trigger guard projecting away from said housing on opposite sides of said trigger switch.
 3. An insect collection device according to claim 1 wherein said plunger shaft proximal end is directly connected to a butt end of said compression chamber.
 4. An insect collection device according to claim 1 wherein said compression chamber is resiliently biased into the uncompressed position and said movable closure is resiliently biased into the closed orientation, yet urged into the open orientation as said compression chamber is returned to the uncompressed position from the compressed position.
 5. An insect collection device according to claim 1 wherein said housing extends along a central longitudinal axis and includes a plurality of tubular housing sections that are selectively matable with one another so that an effective length of said housing may be varied. 